DE4214752A1 - Pump, esp. for oil - comprises two-part plastic housing including cover and stator enclosing pair of abrasion resistant rotors - Google Patents

Abstract

A pump, esp. for oil comprises a two-part plastic housing (10) having a stator (12) and a cover plate (14). Both cover (14) and stator (12) are mfd. in polyethersulphone. Two rotors (22) are housed within a recess (16) in the stator (12) and are attached to a metal drive shaft (20) passing through plastic bearing areas (18,28) in the stator (12) and cover (14). The rotors are moulded, pref. of polyphenylene sulphide, and are injection moulded on the shaft (20). Shaft bearing surfaces (18,28) are abrasion resistant, pref. of PPS or PES. USE/ADVANTAGE - For pumping fluid, esp. oil in motor vehicles. Low wt. and long service life.

Description

The invention relates to a pump, in particular an oil pump, as specified in the preamble of claim 1.

Such pumps, in particular as internal gear pumps are trained specifically in automotive engineering applied and serve there for promotion and printing Impact of engine oil in automotive engines.

Such pumps are made of steel and Made of light metal parts. Here is the receiving part the housing made of aluminum, the cover made of magnesium, and the Rotors are made of steel.

Such pumps are relatively heavy and can therefore hardly be used when it is based on a lightweight construction  Weight reduction or limitation, especially of strength vehicles arrives. In addition, such pumps produce in Operation relatively high running noise, so that they are turned in built state are too loud.

Internal gear pumps with gears are also already out Plastic known, but with problems in location gears occur. In particular, due to of the storage problems the gaps required in the pump between the gears and between the gears and theirs Storage or guide areas too large. Such pumps are therefore not suitable to the required high pumps performance over a longer period of time provide.

Proceeding from this, the object of the invention is to create another pump of the type mentioned in the introduction, which has a long service life with low weight.

According to the invention, this task is performed on a pump gangs mentioned by the characterizing features of Claim 1 solved.

According to the invention, the pump for the rotating parts pe and the bearings of the drive shaft the materials chosen so that no metal / metal engagement or friction pairings to step. The pump rotors become one for very high ones Loaded plastic is used while for the Drive shaft is provided in a metal or plastic according to claim 2 clearly in its strength values of deviates from the plastic used for the pump rotors. As a result, the weight of the pump can be significantly reduced grace, while also their running noises in operation be reduced.  

In the embodiments according to claim 3 and 4 ensures that the operation of the pump, in particular Frictional heat generated in the area of their bearings can be dissipated outside, resulting in a material fatigue and undesired wear of the pump, ins especially in the area of their storage and management areas, ver can be avoided.

The embodiment of claim 5 has not only that Advantage that the heat dissipation is further improved, but also provides a good transmission of downforce forces for the pump rotors safely.

The embodiment described in claims 6 and 7 Games of the invention allow a particularly favorable Her position of the pump.

For an optimal friction pairing between the drive shaft and To get their bearings, the embodiment is according to Claim 8 provided. Through the different festi values, the different elastic moduli of the materials and in particular the surface quality and hardness of the Drive shaft and its bearings will stick the shaft in the bearings prevented.

According to claim 9, these advantages can also with vice returned selected materials can be achieved.

A particularly favorable choice of material is in claim 10 described.

Particularly good results, especially with regard to the Durability, can be reduced with the configurations Claim 11 and 12 achieve.  

To meet the requirements of lightweight construction even better can, the embodiment according to claim 13 is featured see. A plastic can be used for the receiving part choose that with respect to all relatively moving parts is that the optimal friction pairing enables becomes. Here, the developments according to claim 14 and 15 tried and tested. The use of plastic for the receiving part also enables its manufacture in Injection molding technology, which has the advantage of being based on this Parts manufactured in this way without substantial rework can be manufactured.

The invention can be particularly inexpensive Manufacture the pump if at least the receiving part of the housing ses designed according to claim 15 as a hybrid housing becomes. This hybrid construction is due to the good heat dissipation and the favorable friction pairing between the relative to each other moving parts of the pump.

It is particularly preferred if the cover of the housing ent is formed according to claims 16 to 18.

For particularly critical working temperatures when using the Pump is the embodiment according to claim 19 featured see. This achieves even better heat dissipation so that even at the critical working temperatures a Zer placement of the plastics in the area of the bearings can be prevented.

The invention is described below, for example, with reference to Drawing described in more detail; in this shows:  

Fig. 1 shows a schematic section through a pump,

Fig. 2 is a partial sectional view corresponding to line II-II in Fig. 1,

Fig. 3 shows a 90 ° rotated section through the pump according to Fig. 1,

Fig. 4 is a schematic section through another embodiment of the pump.

In the different figures of the drawing, one another corresponding components with the same reference numerals.

Fig. 1 shows a pump with a housing 10 having a receiving part 12 and a cover 14 . The receiving part 12 has a cup-shaped recess 16 and a cylindri cal bearing opening 18 for receiving a drive shaft 20th

In the recess 16 , two gear wheels 22 , 24 serving as pump rotors are made of a plastic designed for very high loads with high abrasion resistance, in particular of polyphenylene sulfide (PPS) or polyether sulfone (PES), one of which is an external gear 22 with internal teeth 23 and the other is an internal gear with external teeth 25 .

As shown in FIG. 2 in particular, the external gear 22 is mounted in the cup-shaped recess 16 and is offset eccentrically with respect to the internal gear 24 , so that the toothings 23 , 25 of the meshing gears 22 and 24 in the recess 16 become one during operation of the Form pump time-changing working space 26 .

The cutout 16 and thus the working space 26 is closed on the side of the receiving part 12 facing away from the bearing opening by means of the cover 14 which has a bearing opening 28 for the drive shaft 20 . At its protruding from the cover 14 , facing away from the receiving part 12 , the drive shaft 20 has a recess 30 which serves for connec tion with a drive means, not shown. The cover 14 is defined by a suitable centering, not shown, fastened to the receiving part 12 of the housing 10 and at the same time serves with its bearing opening 28 as a counter bearing for the drive shaft 20 , which is mounted with its other end in the bearing opening 18 on the receiving part 12 , and to limit the working space 26 .

The drive shaft 20 , which is preferably made of a different material than the gears 22 , 24 , is non-detachably connected to the internal gear 24 for the drive connection. For this purpose, a recess 32 is provided on the drive shaft 20 . The non-detachable connection between the internal gear 24 and the drive shaft 20 is preferably obtained in that the internal gear 24 is attached to the drive shaft 20 by injection molding.

Fig. 3 shows an inlet and an outlet channel 34 and 36 for the pumped medium. The pump can with its receiving part 12 z. B. by means of screws, not shown, on a component 38 schematically indicated in the drawing.

The reference to FIG. 1 to FIG. 10 described housing 3 is made of plastic, preferably made of polyphenylene sulfide or polyether sulfone, is provided while as the material for the drive shaft 20 of metal, preferably steel einsatzhärtbarer.

Although both the housing parts and the pump rotors 18 , 28 can consist of polyphenylene sulfide or polyethersulfone, it is preferred to produce the housing parts and the pump rotors 18 , 28 , which are in frictional engagement with one another, from different plastics. In this case, polyphenylene sulfide (PPS) and 10 polyether sulfone (PES) are preferably selected for the pump rotors 18 , 28 . A polyphenylene sulfide mixture with approximately 20% by weight of carbon fiber reinforced plastics has proven particularly useful.

With this construction of the pump and in particular of the housing, the bearings for the drive shaft 20 , which are formed by the bearing opening 18 in the receiving part 12 and the bearing opening 28 in the cover 14 , as well as the surfaces on the receiving part 12 or the surfaces delimiting the recess 16 in the receiving part 12 on the cover 14 , which serve as bearing or guide surfaces for the gears 22 , 24, are not specially designed, so that there is a simple and inexpensive construction of the pump, which can be realized inexpensively by suitable manufacturing processes.

The pump shown in Fig. 4 has a receiving part 12 with a base part 12 ', in which a suitably shaped lining element 40 made of polyphenylene sulfide or polyether sulfone is inserted, so that the recess 16 and the bearing opening 18 delimiting surfaces from one for very high Load-bearing plastic with high abrasion resistance are formed. The base part 12 'can also be made of cheap glass and / or carbon fiber reinforced plastic.

In a corresponding manner, the cover 14 consists of a base part 14 ', which is made of glass and / or carbon fiber reinforced plastic, and on which to cover the savings 16, a covering plate 42 made of polyphenylene sulfide or polyethersulfone is attached. The bearing opening 28 in the lid 14 is provided in a sleeve 44 which is inserted into the base part 14 'and also consists of poly phenylene sulfide or polyether sulfone.

Due to the described structure of the pump, an optimal friction pairing of plastic (PPS or PES) against hardened steel is obtained at the bearings for the drive shaft 20 . The different strength values and the different moduli of elasticity of the different materials as well as their different surface properties and hardness prevent the drive shaft 20 from sticking in the bearing openings 18 , 28 .

Another advantage of the pump described is that frictional heat occurring during operation from the bearings via the solidly formed drive shaft 20 made of steel can be carried out well, so that there is no premature wear of the bearings.

In order to obtain an even better heat dissipation at critical working temperatures, the cover 14 can also be made from a magnesium alloy.

In order between the input shaft 20 and its bearings 18, 28 to obtain the desired metal / plastic friction pairing, the bearings 18, 28 are made of metal and the drive shaft 20 of a suitable plastic material. The bushing 44 shown in FIG. 4 and the lining part 40 or its bushing section forming the bearing opening 18 can then be made of metal. With such a structure, the lightweight construction made possible by the use of plastic need not be dispensed with.

Claims (19)

1.Pump, in particular an oil pump, with a housing which has a receiving part with a recess for receiving two drive rotors which are in engagement with one another and which limit a working space which changes over time during operation, and a cover which covers the recess, and with a drive mounted on the housing Shaft which is passed through a corresponding opening in the cover and / or in the receiving part and which is in drive engagement with one of the two pump rotors, characterized in that the two pump rotors ( 22 , 24 ) consist of a plastic designed for very high loads, and that the drive shaft ( 20 ) and their bearings ( 18 , 28 ) are so formed that a metal / plastic friction pairing is present in their bearings. 2. Pump according to claim 1, characterized in that the drive shaft ( 20 ) consists of a material whose strength is greater than that of the plastic used for the pump rotors ( 22 , 24 ). 3. Pump according to claim 1 or 2, characterized in that the drive shaft ( 20 ) is solid. 4. Pump according to claim 1, 2 or 3, characterized in that the drive shaft ( 20 ) consists of a material with high thermal conductivity. 5. Pump according to one of the preceding claims, characterized in that the drive shaft ( 20 ) consists of metal, preferably of hardened steel, in particular of a hardenable steel. 6. Pump according to one of the preceding claims, characterized in that the drive shaft ( 20 ) with the pump rotor ( 24 ) driven by it is non-detachably connected. 7. Pump according to claim 6, characterized in that the pump rotor ( 24 ) is attached to the drive shaft ( 20 ) by injection molding. 8. Pump according to one of the preceding claims, characterized in that the drive shaft ( 20 ) in at least one bearing ( 18 , 28 ) made of a plastic with high abrasion resistance, preferably made of polyphenylene sulfide (PPS) or polyether sulfone (PES), in the housing ( 10 ) is stored. 9. Pump according to claim 1, 2 or 3, characterized in that the drive shaft ( 20 ) made of plastic and the bearing openings ( 18 , 28 ) for the drive shaft ( 20 ) on pointing parts ( 12 , 40 , 14 , 44 ) Metal, preferably made of hardened steel, in particular of case hardenable steel. 10. Pump according to one of the preceding claims, characterized in that the pump rotors ( 22 , 24 ) consist of a plastic with high abrasion resistance. 11. Pump according to claim 10, characterized in that the pump rotors ( 22 , 24 ) consist of polyphenylene sulfide (PPS). 12. Pump according to claim 11, characterized in that the pump rotors ( 22 , 24 ) made of polyphenylene sulfide (PPS), to which about 20% carbon fiber reinforced plastics are added. 13. Pump according to one of the preceding claims, characterized in that the receiving part ( 12 ) consists of plastic. 14. Pump according to claim 12, characterized in that the receiving part ( 12 ) made of a plastic with high abrasion resistance, in particular polyethersulfone (PES), be. 15. Pump according to claim 13, characterized in that the receiving part ( 12 ) consisting essentially of glass and / or carbon fiber reinforced plastic in the region of the surfaces ( 16 ) delimiting surfaces and the bearing ( 18 ) made of a plastic with high abrasion resistance, preferably made of polyethersulfone (PES). 16. Pump according to one of the preceding claims, characterized in that the cover ( 14 ) consists of plastic. 17. Pump according to claim 16, characterized in that the cover ( 14 ) made of a plastic with high Abriebfestig speed, in particular made of polyethersulfone (PES). 18. Pump according to claim 16, characterized in that the substantially made of glass and / or carbon fiber reinforced plastic cover ( 14 ) in the area of the recess ( 16 ) delimiting surface and the bearing ( 28 ) made of a plastic with high abrasion resistance , preferably made of polyethersulfone (PES). 19. Pump according to one of claims 1 to 15, characterized in that the cover ( 14 ) made of light metal, preferably made of a magnesium alloy.